Small hole polarons in yellow phase 𝛿−CsPbI3

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Small hole polarons in yellow phase 𝛿−CsPbI3
Title:
Small hole polarons in yellow phase 𝛿−CsPbI3
Journal Title:
Physical Review Materials
Authors:
Keywords:
Publication Date:
10 June 2025
Citation:
Liu, Y. (2025). Small hole polarons in yellow phase 𝛿−CsPbI3. Physical Review Materials, 9(6). https://doi.org/10.1103/yr22-9j6r
Abstract:
A heterophase containing both the optically active α-CsPbI3 and nonactive δ-CsPbI3 has been demonstrated as an efficient white light emitter. This has challenged the conventional perspective that nonactive phases of perovskites are undesirable in any metal halide perovskite-based optoelectronic devices. To understand the role that yellow phase δ-CsPbI3 plays in the light-emission process, we performed a systematic computational study on its electronic and optical properties, which are relatively unexplored in the literature. Using the Fröhlich model we showed that both the electron and hole exhibit moderate coupling to longitudinal optical phonons. Explicit density functional theory calculations show that small hole polarons exist with a formation energy of −96 meV, corresponding to the contraction of the Pb-I bonds within a [PbI6 ] octahedron. Nudged elastic bands calculations show that the hole polaron can hop into neighboring [PbI6 ] octahedral sites with a small activation barrier of 2.1 meV. Molecular dynamics simulations also show that the hole polaron exhibit periodic localization and delocalization behavior similar to carrier hopping with a characteristic lifetime of 0.3 ps. Our results have elucidated the role that δ-CsPbI3 plays in the self-trapped emission in perovskite-based white light emitting diodes by supporting the presence of the localized small hole polaron.
License type:
Publisher Copyright
Funding Info:
This research / project is supported by the A*STAR - Career Development Fund
Grant Reference no. : C233312001
Description:
ISSN:
2475-9953
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